Pressure-actuated tool.



G. H. GILMAN.

PRESSURE ACTUATED TOOL.

APPLICATION FILED NOV. I3. 1908.

1,143,533. Patented June 15, 1915.

3 SHEETSSHEET I.

Zfinassas Imp/cantor: 5mm aQ i jqeliliwillrnan. g 7(M I ,9 M

G, H GILMAN.

PRESSURE ACTUATED TOOL.

APPLICATION mm) NOV. 13. 2908.

Patented June 15, 1915.

SHEET 2.

3 SHEETS- Geoigg $m a m mg 101L612 eases 56 G. H. GIL-MAN.

PRESSURE ACTUATED TOOL.

A P P L l C A T l 0 N F l L E D N 0V 13, 1908- 1 ,14;3,533a Patented June 15, 1915.

E9 I 1 115 .15 4g? EEEEEE 2 5 WWW-WM. y 21 flasks s re " ran GEORGE H. GILMAN, OF GLAREMONT, NEW KAMPSHIRE, ASSIGNOB, BY MESNE ASSIGN- IMENTi, TO SULLIVAN MACHINERY COMPANY, GE BOSTON, MASSACHUSETTS, A

CGRPORATIQN OF MASSACHUSETTS.

ERESSUBE-ACTUATED TOOL.

Specification of Letters Patent.

Patented'dune 15, 1915.

Application filed November 13, 1908. Serial No. 462,402.

t known that I, Gnoncn H. GILMAN,

tion with the acccmpa ymg drawings, is a specification, like letters on the drawings representing like parts.

' invention relates to pressure-actuated tools being more particularly concerned with the provision of improved feeding devices for such tools and with improvements inv the pressure-actuated controlling valves for the tools th iselves.

My invention will be best understood by reference to the following description when talron in connection with the accompanying illustration of one specific embodiment thereof. while its scope will be more particularly pointed out in the appended claims.

ln the drawings: Figure 1 shows in side elevation, partly broken away, a pressurefed hammer drill embodying one formof myinvention; Fig. 2 shows in plan adetail, on

an enlarged scale, of the clamp for the tool bushing; 3 is a transverse section in elevatidn taken on the line 3-3 in Fig. 2; lshows a central, longitudinal section in elevation of the forward end of the hammer drill cylinder together with the tool bush. Ag and clamp; Fig. 5 is a central, sectional elevation or a portion of the support ing or abutting end of the feed cylinder; Fig. .6 is a sectional elevation on the line 6-6 in Fig. Fig. 7 is a'plan, on an enlarged scale, of the head block and its connections to the tool and feed cylinders; Fig. 8 is a longitudinal section in elevation of the-same taller.- on the line 88 in Fig. 7; Fig. 9 is a sect-ion in plan on the line 99 in Fig. 8 showing the oiling passages; Fig. 10 is a section, on an enlarged scale, showing. the controlling valve for the hammer drill; Fig. ll is a similar section sliowing the valve in another position; Fig. 1?: is a section in plan,

on the line 12l2 in Fig. 8, showin the relation of the motive fluid passages when the throttle valve is wholly shut oil; Fig. 13 a similar section on the line l3-13 in Fig. 5 and showing the same position of the throttle valve; Figs. 14: and 15 are sections similar to Figs. 12 and 13, respecti vely, but

ure-Actuated lools, of which the following description, in eonnec showing the relationof the motive fluid passages when the valve has been turned initially to admit fluid to the feeding cylinder while still shutting off from the tool Figs. 16 and 17 are sections similar to Figs. 12

and 13, respectively, showing'the relation of 0 the fluid passages when the valve has been turned to admit fluid bdth to the feeding cylinder and the tool; and Figs. 18 and 19 are sectionssimilar to-Figs. 12 and 13, re-

spectively, showing the relation of the same passages when the valve has been turned to shut off the pressure fluid from the feed cylinder while still admitting it to the tool.

Referring to the drawings and t0 the embodiment of my invention which I have 7.0

there disclosed for illustrative purposes, I have there shown a pneumatic tool, herein of the hammer drill type, having the .cylinder 150 connected to suitable pressure-actuated feeding apparatus that the pressure fluid 7 supplied thereto through the pipe 2 acts not only reciprocatively to move the hammer piston 3 against the shank of the cutter bit or drill 4, but also acts initially to advance the tool toward the work and hold the drill forcibly pressed against the same While the tool is in operation, all as represented in 7 Fig.1.

While pressure-actuated feeding means of any suitable construction may be employed, 8

herein I have provided a feeding cylinder 5 adapted to cooperate w th a suitable feeding piston 6 (see Fig. 8) therein contained. Either the piston or the cylindciyas desired,

may be connected to the tool, the remaining 96 part serving to support theapparatuseither by abutment against a wall or other support (as represented in Fig. 1'), or by direct attachment to some suitable support. In the present instance the piston 6 serves as the abutting or supporting member, the cylin der being rigidly secured to the tool to move therewith on the support which isprovided by the fixed piston.

lnthe present form of apparatus the pres 100 sure fluid for actuating the feed and the tool is controlled through a throttle valve, the handle for which is represented at 7, such.

valve being mounted in the connecting piece S interposed between and rigidly secured to the feed cylinder 5 and the tool cylinder 1.

In devices oi 'this class great troublehas been experienced from the employment of threaded joints for securing the feed and tool parts together and difliculty been found in providing an attachment suitable for holding the parts securely together while capable of withstanding the severe vibratory strains to which they are subjected forward end when usedin the mine.

In the present construction I have provided accurately fitting slip joints between the feed cylinder and the connecting piece on the one side and the toolcylinder and connecting piece on the other, and have also provided meansfor clamping such parts securely together Without the use of threaded joints between the parts, and preferably through the employment oi? tapered or conical clamping means. v

Referring more particularly to the construction shown in Figs. 7 and 8, the for- Ward or inner end of the feed cylinder is provided with outwardly flared tapering walls-9, and the sameis fitted over a reduced projecting portion 10 of the connecting piece, a packing-ring ll being preferably employed to make the slip joint thus provided pressure tight. At the opposite or of the connecting piece there is provided the shell 12 fitted about and slipped over the valve block 13 and its end plate Maud also over a short end portion of the cylinder 1.v The latter, closely adjacent the shell portion of the connecting piece 8 is i also provided with tapered walls 15, similar to the tapered portion 9 on the feed cylinder, but reversely arranged. With the parts in the positionshown they are all clamped rigidly together by means of the clamping collars 16 and 17, which latter have tapered openings to fit over the tapered Walls of the feed cylinder and tool cylinder, respectively, and are united and clamped together by means of the tie bolts 18- and the clamping nuts 19, the bolts passing through lateral ears on the clamping collar. This provides a perfectly rigid connection for the feed cylinder, tool cylinder and the intervening connecting piece without the use of threaded joints, and affords a connection capable of holding together under the most severe usage.

Referring now to Figs. 1, 5 and 6, at the opposite or supporting end of the feed cylinder, provision is made for a plug orguiding piece for the piston rod inserted in the end of the cylinder and there retained without the use 01 threaded joints orthreaded connections. \Vhile this may be cllccted in various ways, in the present instance there is provided a plug-9.0 provided with a head and having a reduced portion fitting the end of the cylinder into which it is stepped. The plug not only closes the end of the cylinder but provides a guide for the end of the piston rod 2], which latter terminates in the foot or pivoted end 22 adapted to abut roiirdinaicly controls thh against afixed support, such as the wall shown in Fig. 1. v

In assembling the apparatus the plug is inserted and a U-shaped retaining 'device is then driven into suitably drilled trans'yersc holes in the walls of thecylinder andhjofthe plug. The projecting ends of the retaining member (represented in dotted line, Fig. 6)

are then bent over against the cylinder, there shown, thus eilectually locking the piece against displacement no matter howgreat the vibration may be to which the apparatus is subjected. On the other hand, if it is desired to dismantle the apparatus, or remove the piston for any purpose, the plug may be withdrawn by straightening out the ends of the insertion member or key and To lfleieni] either rotative or longitudinal displacement of the bushing the latter is held fixed in the end of the cylinder by a key bolt'26 lying transversely across the bushing. The key is carried in the split clamping piece 27, which is adapted to he slipped over the end of the cylinder and receive the key, and the latter is provided with an inclined bushing engaging wall 28 adapted to seat in. a corespondingl y shaped.

groove or recess in the bushing, so that,

I clamped into position by the key. The walls of the cylinder are transversely cut away to.

when the bolt is clamped up the key seats in i the bushing recess and the bushing is locked rigidly against displacement of any kind within the cylinder. By unloosening the clamping nut 23) the key may be moved latorally far enough to permit the mineral of the bushing without the withdrawal of the key fromthe cylinder. Preferably, though not necessarily, the cylinder is split as at 30 for a short distance from its end, so that the bushing can he slipped freely in and out of the cylinder, "while, at the same time, it may be clamped tightly within the cylinder when the clamping nut 29 is tightened.

- Referring now'to thothrottlc val vc which pressure feed and thetool, such valve is ignatcd by the numeral 31 (Fig. 8) andis arranged transversely the connecting piece 8, being pr vidod with pasagcs so arrangml that it acts to secure a variety of coiipcrative actions in the tool and the feed.

Tosupply motive fluid to they valve, the end of the latter has the central opening or of the bQOl by. 1

supply chamher jacent opening 35 From the valve s are provided two is v passages 3% 1i. admit fluid to'the feed main feed cylinri the apparatus is passage acting, operation, to a chamber o' 1 re y r Beyond the i111 32the throttle v transverse passa cally 'acr ss the feed cylinder with chamber V 37 i .he cylinder exit passage $0 on the one side -11 main tool supply pass on the other. Means are also pro idea jor placing fee-(l. cyhnder in communication with the atmosphere, such means h 1 ccinprls' duct or passage a2 estczunnp lat I the Walls of the conne the throttle valve and ai i. in connnrnu iation wi h the exit passage all in oer l. .4

valve by means of a grow.

the side of the throttle, such pcc at being shown in F g. 12-3.

Referring now to l i the movement oi the tn ottlc valve "for controlling the apparatus will now he a When the tool out 0: i e t turned to the pr loan 7 13, pressure thud suppl of the valve being: on shut on tothe teed cylincer. the

T 1 7 o no placed latter is opened to the atn'io the exit passage so, the

atmospheric e attachment is incl Fecal waiting any feeding movement to the At the same time the tool 15 oii' from the pressure liind,vboththe main supply a1 and the, auxiliary DUDE by he throttle valve. The tool. in in this a-tion to spot thcscle by dril (:ient. depth to insure th cunt (lrillbefore the full pre re t ,thetool.

ing of the rned on to 4 mitted through the central opening- In Figs. 1a and 15 I have shown the position to which the throttle is turned for ad initting the initial pil'essure to the feed 1' ton to position the drill. With the Va turned to this'position, the pass so has just begun to open into the passage 3i, ther by admitting a restricted amount of pressure fluid to advance the tool and the cutter gradually against the Work. Before this ocr the atmospheric passage has been shut oil from the cylinder exit passe l0, the pressure, as before, still rein? 115 out off from the tool,

moved from the position shown in and 15 to that shown in Figs. 16 and ll which shows the passage arrangement I the tool operating under full UOilZ in bringing the valve to this position, the operative Will ordinarily dwell it at thepoin't oi initial fluid admission to the tool sullieion U to insure the spotting action referred to. In the lull-open position of the valve shown in Figs. 16 and 1?, pressure liuid being adand the passages 34; and 36 to the feed rvlinder and thence, through'the cylinder exit if sage 4:0 and the transverse valve pas to the main tool inlet port ll and the pressure chamber of the tool. It will he seen that, under these conditions, the valve be slightly moved to give either a full supply of motive fluid to the tool as shown) or a reduced supply throttled down to any desired extent. y

In the use of apparatus of this type t is pockets or other formations are frequently encountered which suddenly Withdraw op position to the advance of the cutting: hit and if the full feeding pressure is at that tine effective, the tool with its hit will spring forward until the hard rock is again encountered, frequently binding or cramping the bit into some position from which it must be extracted with considerable. lahor ire the clrillingj can proceed. ride for this or other contingencies, I have shown means for diminishing the feeding eilort at times to any required'ainount that, when pockets or other like conditions are encoui'iteicd, such means may he availed of. In the described form ofthrottle valve, the passages are so arranged that, by turning the throttle to the position shown in Figs. lSand 19 motive fluid may be admitted directly to the pressure chamber of the tool from the supply chamber 32 through the lateral passage 35 and the auxiliary passage 36, thereby maintaining the full operain a y v To proadapted to receivcvthe tion of the tool while shutting oil" the feed cylinder from the pressure fluid as well as the atmosphere. This results in bottling up or trapping the pressure fluid remaining in,

direction of the arrow shown in Fig. 19,-

thereby connecting the feed cylinder with the atmosphere through the passages 40 and 4-2, and lowering the pressure therein to any desired degree. In )assing from the position shown in Fig. 1 to that shown in Fig. 19, these atmospheric passages are momentarily placed in communication, but the interval is so slight, unless purposely maintained, as to be of no effect in lowering the pressure of the fluid trapped in the feed. It will therefore be seen that the throttle valve may be moved to a variety of positions for the purposes described, thereby eiiecting complete control over the feed and the tool.

Preferably means are provided such as the stud 4-1 fixed inthe upper face of the connecting piece 8 and coiiperatiug with the groove 4-5 in the under face of the handle 7 to limit "the throttle valve to a range of movement sutiicient only to give the desired connections.

In 01 .ier to position the valve in the various positions to which it will customarily be turned, while, at the same time, permitting graduated movement thereof, any suitable means may be provided, but herein there is shown the spring-pressed positioningpin if) working in a lateral pocket in the connecting piece 8 and pressed against the outer ,walls of the throttle valve, which latter is provided with a plurality of depressions end of the pin. The end of the latter is rounded so that it yields readily to themovement of the throttle, bit when one of the openings oi thelatter is brought into registration with the pin the latter slips into 'tion the throttle and there hold the same against accidental displacement.

The proper lubrication of a device of this class often a matter ofdilliculty and, here shown in connection with the described in-,

.vcntion, I have provided lubrication means preferably C()il])(1:1tlllf f with the controlling throttle valve. For this purpose there is herein 1 )].O -'i(l((l an annular lubricant chamher 47 in the connecting piece, such chainber surrounding the reduced portion l8 oi thrthrottle valve stem. Such chamber is adapted to be filled with lubricant through the passage 49 (Fig. 7), the latter being closed by. the-threaded plug 50.

her formed between the opcnlng and helps posi- To feed the lubricant from the lubricant chamber to the tool in restricted quantities,

lubricant Cllli'EbGI and, when the valve is turned to the inoperative positlon shown in Figs. 12 and 13, connects such chamber with a small oil retaining pocket 53 formed in the opposing walls of the connecting piece and causes the filling of such pocket with lubricant. When the valve is subsequently turned to start the apparatus into operation, this lubricant is trapped in the pocket 53.

When the valve reaches the position shown in Figs! 16 and 17 the groove 52 is brought into registration with the oil pocket. The groove 52 opens into the valve passage 39, through which the pressure fluid passes to the tool, so that such lubricant is then released and carried over by the motive fluid passing through the passage across the open mouth of the groove 52.

Each time that the valve is turned to the inoperative position the oil pocket is again filled and, when the tool is started into operation, the lubricant retained thereby is carried into the working insures lubrication of the tool without waste of lubricant and without attention on the part of the operator save to maintain a supplvof lubricant in the chamber 17.

Referring now to the construction of the tool and more particularly to that of the controlling valve therefor, attention is directed to the construction shown in Figs. 4, 8, 10 and 11. It will there be seen that the piston hammer 3 is in the form of a straight ungrooved cylindrical bolt, which delivers its blows against an anvil member 54 inter-v posed between the drill shank iland the piston. Movements of the piston are directed by means of the pressure-actuated contrailing valve 55 preferably in the form of a cylindrical shell and working in a valve chamthe valve block 13 and the end plate 14.

. The valve is preferably in the form of a hollow spool having a central circumferenparts of the tool. This s and 58, of which the latter at all times, in communication with the circumferential groove 56. To such annular groove there is constantly admitted motive fluid through the longitudinal passages 60 which extend rearwardly through the valve block and end plate to the constant pressure chamber 13.

To admit motive fluid to and exhaust the same from the rear or Working end of the tool cylinder, the latter is connected, herein by a plurality of rearwardly extending pas sages 61 with a cylinder port in the valve chamber, herein in the form of an annular groove 62 located at the front 01 the annular groove 59.

To admit motive fluid to and exhaust the same from, the forward or tool end of the cylinder, the forward end of the latter (Fig. i) has opening into the same a return pressure port 63 extending longitudinally through the cylinder walls and the valve block (Fig. 8) opening into the valve chamber through the transverse port 6%, which latter is located immediately at the rear of the annular groove 59.

It will therefore be seen that, with the valve in the forward position shown in Fig. 10, the annular groove 59 is connected with the rear end of the tool cylinder, and, in

the position shown in Fig. 11, with the forward end thereof, pressure being admitted in the first case to drive the piston forward to impart the striking blow and, in the latter case, to return the piston rearwardly.

For the exhaust there is provided the lateral exhaust passage 65 opening into the atmosphere through the valve block plate on the surrounding shell 12 of the connecting member and placing the hollow interior of the valve in communication at all times with the atmosphere.

The plate 1% and the valve block are provided with projecting wall portions 66 and 67, respectively, which fit the interior diameter oi the valve and over which the valve is adapted alternately t slide, acting, in the forward position, to uncover the projection 66 and open the rear of the valve chamber to the interior of the valve and, in the rearward position to uncover the projection 67 and open the forward end of the valve chamber to the interior of the valve. The proportions are such that, in the forward position the hollow interior of the valve and, therefore, the atmosphere, is connected directly with the port 64: and thereby with the forwr the rearward position, the valve interior is connected through the annular groove 62 and passage (ll with the rear end of the cylinder.

Any suitable means may be employed for eflecting pressure-actuated movement of the valve, but herein passages are provided opening into the opposite ends of the yalve d end of the tool cylinder, while, in-

chamber and communicating with the tool cylinder at diiierent points'in its length. One passage 68 communicates at one end with the forward end of the valve chamber (see Figs. 8 and 11) and at the opposite end with the tool cylinder (see Fig. 4:) in such a position as to be uncovered to the motive fluid at any suitable time prior to the time the piston strikes its blow. This causes niotive fluid to be admitted to the larger or forward area of the valve, moving the latter from the position shown in Fig. 10 to that shown in Fig. 11. In addition there is also provided a second valve-actuating passage 69, opening at one end through a transverse port into the rear end of the valve chamber, and at its forward end into the tool cylinder at a point in advance of the passage 68 and where it will be uncovered to the motive fluid by the piston on the return movement of the latter. At such time the valve being in the position shown in Fig. 11, the largerend pressure area is exposed to the exhaust, while the motive fluid admitted through the passage 69 and the port 70 to the smaller end pressure area, acts tomove the valve from the position shown in Fig. 11 to that shown in Fig. 10.

From the foregoing description of the construction of the valve and the arrangement of its various ports and passages. its operation will be clear. With motive fluid admitted to the constant pressure chamber 13 and the valve shown in the position in Fig. 10, fluid is admitted to the rear end of the tool cylinder to drive the piston forward through the longitudinal passages 60, the annular groove 59 in the valve chamber, the circumferential groove 56, the annular groove 62 and the cylinder admission passages 61. At the same time fluid is exhausted from the forward end of the tool cylinder through the return pressure port 63, the valve chamber port 64, the hollow interior of the valve and the exhaust passage 65.

lVhen the valve has reached a position sufliciently advanced to uncover the valve controlling port 68, motive fluid is admitted to the forward end of the val vo chamber and against the larger area of the valve, acting to reverse the latter and move it to the position shown in Fig. 11. In this position of the valve, pressure fluid is admitted to the forward end of the tool cylinder from the constant pressure chamber 18 through the longitudinal passage 60, the annular groove 59 of the valve chamber, the circumferential valve groove 56, the port (i l and the return pressure port 63. At the same time fluid is exhausted from the rear end of the tool cylinder through the cylinder port 61. annular groove 6'2, the hollow interior oi the valve and the exhaust port 6:3.

During the operation of the tool and with the drill pressed against the work by the the tool, together with the entire feeding-apparatus, may be oscillated or rotated suliicientl y to impart the necessary turning movement to the tool.

While I haveherein shown and described for the purpose of illustration one concrete form or embodiment of my invention, it is to be understood that the same is not limited to the details of construction, orrelative form or arrangement of parts, or to the application herein made of the various features thereof, but that the same may be modified within wide limits without departing from the spirit of the invention.

Having thus described my invention, what I claim is: I

1. In a tool feeding device, the combination with a pressure-actuated tool. of a pressure-actuated feeding device therefor, 21 throttle valve and means permitting said valve to be placed in one position to open the feeding device to the motive fluid While cutting off motive fluid from the tool, and in another position to open the tool to the motive fluid While cutting off motive fluid from the feeding device and means to;

enforce the occurrence of the enumerated operations in'thc order named and in reverse order.

2. In a tool feeding-device, the combination with a pressure-actuated tool. of a pres sure-actuated feeding device therefor, a throttle valve and means permitting the latter to be placed in one position to connect both the tool and the feeding device with the pressure fluid, and in another position to cut off the pressure fluid from the feeding device while trapping a portion thereof therein, and, at the same time, leaving the tool open to the pressure iiuid and means to enforce the occurrence of the enumerated operations in'thc order named and in reverse order. v

3. In a tool feeding device, the combination with a. pressureactuated tool, of a pressure-actuated feeding device, a throttle valve, and means permitting said valve to be placed in one position to open the feed ing" device to the pressure fluid and in an other position to trap a. portion of the mo live fluid therein While adn'iitting motive fluid to the tool. to cause the operation lIl'l'{3Ilof, said valve also heing adapted for u1ovcment to exhaust more or less of the motive lluid thus trapped in the feedingdevice.

4. To a tool. feeding devioc, the co'ml'iinatime with a Pl't. $lll'(-t.(fl(Hlffll tool, of a pres sure-actuat uli'eedingdrvice, and means for initiating the operation of said tool and named and in reverse order;

feeding device and subsequently causing the operation of the feeding device on pressure fluid stored therein, While continuing the pressure-actuated operation of the tool.

5. In a tool feeding device, the combination With a pressure-actuated tool, of a pressure-actuated feeding device, means for causing the operation of the feeding device on pressure fluid stored therein, While continuing the pressure-actuated operation of the tool, and means for adjustably exhausting more or less of the pressure fluid stored in the feeding device to vary the feeding efi'ort thereof.

6. In a tool feeding device, the combination With a pressure-actuated tool, of a pressure-actuated feeding device, a throttle valve, and means permitting the latter to be placed in one\ position to .cut off motive fluid from oeue the tool and the feeding device While opening the latter to the, atmosphere, in another position to admit motive fluid to the feeding device While cutting it off from the tool, in a third position to ad mit fluid both to the tool and the feeding device, and in,a fourth position, While still continuing to admit fluid to the tool, to out "off motive fluid from the feeding device for operating the letter on the pressure trapped therein.

7. In a mechanism of the character set forth, the combination with a motor of motive fluid operative means for feeding the motor to its'ivork, means for delivering the motive fluid to the feed means and conductingr it therefrom to the motor, to initiate the operation of the latter and means for causing the operation of the feedingmeans on pressure fluid stored therein While continuing the pressiu'e-actuated operation of the motor.

8. In a tool feeding device, the combination with a pressure-fluid actuated tool, of a pressure-fluid actuated feeding device therefor, a tl'i'rottlevalve, and means permit ti ng'said valve to he placei'l in one position to cut off motive fluid to the tool and feeding device, while placing the latter in comnuuiication with the atmosphere, in another position to open the feeding device to n motive fluid while cutting off motive ifi'uid from the tool, and in stillanotherposition to open the'tool towthe motive fluidwhile cuttingoff motive fluid from the feeding device and means to enforce the occurrcnceof the enumerated operations in- .iillfi order 9. in a. tool feeding device, thecomhination with a pressure fluid actuatedtool, of :1 pr 1re-fluid actuated fcedingmdevice there a--s'u'iveled throttle :valve' and means cooperating.therewith. having" pro: \lflUIl for causing a continuous movement of said throttie naive in one direction, first,

to: supply motive fluid to the *feedingnde:

to the feeding device While still continuing to supply motive fluid to the tool, and means to limit the turning movement of said valve to less than three hundred and sixty degrees.

10. In a tool feeding device, the combination with a pressure fluid actuated tool, of a pressure fluid actuated feeding device therefor, a swiveled throttle valve and means coiiperatingtherewith having provision for causing a continuous movement of said'throttle valve in one direction, first, to supply motive fluid to the feeding device while Withholding motive fluid from the tool, second, to supply motive fluid, to both the feeding device and the tool, and, third, to cut elf the supply of motive fluid to the feeding device While still continuing to supply motive fluid to the tool, all Within a turning movement of less than two hundred and seventy degrees.

11. In a tool feeding device, the combination with a pressure fluid actuated tool, of a. pressure fluid actuated feeding device there-for, a swiveled throttle valve and means coiiperating therewith having provision for causing a continuous movement of said throttle valve in one direction, first, to supply motive fluid to the feeding device While Withholding motive fluid from the tool, sec end, to supply motive fluid to both the feed ing device and the tool, and third, to cut' oil the supply of motive fluid to the feeding device While still continuing to supply motive fluid to tne tool, all Within a turning movement of less than one hundred and eighty degrees.

12. In a tool feeding device, the combination with a pressure fluid actuated tool, of a pressure fluid actuated feeding device there for, a siviveled throttle valve and means cooperating therevvith having provision for causing a continuous movement of said throttle valve in one direction, first, to supply motive fluid to the feeding device While Withholding motive fluid from the tool, second, to supply motive fluid to both the feeding device and the tool, and third, to cut otf the supply of motive fluid to the feeding device While still continuing tosupply' motive fluid to the tool, and means to limit the turning movement of the valve to less than one hundred and eighty degrees.

13. In a tool feeding device, the combination with a pressure fluid actuated tool, of a pressure fluid actuated feeding device therefor, a throttle valve and means coiperating therewith having provision for causing a continuous movement of said throttle valve in one direction, first, to supply motive fluid to the feeding device while with holding motive fluid from the tool, second, to supply motive fluid to both the feeding device and the tool, and third, to cut of the supply of motive fluid to the feeding device while still continuing to supply motive fluid to the tool, and means for enforcing the occurrence of the enumerated operations in the order named or in reverse order.

1%. in a tool feeding device, the combination with a pressure fluid actuated tool, of a pressure fluid actuated feeding device therefor, a throttle valve and means coiiperating therewith for causing a continuous movement of said valve in'one direction first, to supply motive fluid tothe feeding device While withholding motive fluid from the tool, and second, to supply motive fluid to both the feeding device and the tool, and means for enforcing the occurrence of the enumerate-d.operations in the order named and in reverse order.

In testimony whereof, l have signedmy name to this specification, in the presence of.

two subscribing Witnesses.

. GEORGE E, SILMAN.

Witnesses W. P. J. Dmsrroon, S. Bowers Krlve. 

